Neuroendocrine (NE) prostate cancer (NEPC) is a lethal subtype of castration-resistant prostate cancer (PCa) arising either de novo or from transdifferentiated prostate adenocarcinoma following androgen deprivation therapy (ADT). Extensive computational analysis has identified a high degree of association between the long noncoding RNA (lncRNA) H19 and NEPC, with the longest isoform highly expressed in NEPC. H19 regulates PCa lineage plasticity by driving a bidirectional cell identity of NE phenotype (H19 overexpression) or luminal phenotype (H19 knockdown). It contributes to treatment resistance, with the knockdown of H19 re-sensitizing PCa to ADT. It is also essential for the proliferation and invasion of NEPC. H19 levels are negatively regulated by androgen signaling via androgen receptor (AR). When androgen is absent SOX2 levels increase, driving H19 transcription and facilitating transdifferentiation. H19 facilitates the PRC2 complex in regulating methylation changes at H3K27me3/H3K4me3 histone sites of AR-driven and NEPC-related genes. Additionally, this lncRNA induces alterations in genome-wide DNA methylation on CpG sites, further regulating genes associated with the NEPC phenotype. Our clinical data identify H19 as a candidate diagnostic marker and predictive marker of NEPC with elevated H19 levels associated with an increased probability of biochemical recurrence and metastatic disease in patients receiving ADT. Here we report H19 as an early upstream regulator of cell fate, plasticity, and treatment resistance in NEPC that can reverse/transform cells to a treatable form of PCa once therapeutically deactivated.
Regulation of mRNA stability and translation plays a critical role in determining protein abundance within cells. Processing bodies (P‐bodies) are critical regulators of these processes. Here, we report that the Pim1 and 3 protein kinases bind to the P‐body protein enhancer of mRNA decapping 3 (EDC3) and phosphorylate EDC3 on serine (S)161, thereby modifying P‐body assembly. EDC3 phosphorylation is highly elevated in many tumor types, is reduced upon treatment of cells with kinase inhibitors, and blocks the localization of EDC3 to P‐bodies. Prostate cancer cells harboring an EDC3 S161A mutation show markedly decreased growth, migration, and invasion in tissue culture and in xenograft models. Consistent with these phenotypic changes, the expression of integrin β1 and α6 mRNA and protein is reduced in these mutated cells. These results demonstrate that EDC3 phosphorylation regulates multiple cancer‐relevant functions and suggest that modulation of P‐body activity may represent a new paradigm for cancer treatment.
The Pim and AKT serine/threonine protein kinases are implicated as drivers of cancer. Their regulation of tumor growth is closely tied to the ability of these enzymes to mainly stimulate protein synthesis by activating mTORC1 (mammalian target of rapamycin complex 1) signaling, although the exact mechanism is not completely understood. mTORC1 activity is normally suppressed by amino acid starvation through a cascade of multiple regulatory protein complexes, e.g., GATOR1, GATOR2, and KICSTOR, that reduce the activity of Rag GTPases. Bioinformatic analysis revealed that DEPDC5 (DEP domain containing protein 5), a component of GATOR1 complex, contains Pim and AKT protein kinase phosphorylation consensus sequences. DEPDC5 phosphorylation by Pim and AKT kinases was confirmed in cancer cells through the use of phospho-specific antibodies and transfection of phospho-inactive DEPDC5 mutants. Consistent with these findings, during amino acid starvation the elevated expression of Pim1 overcame the amino acid inhibitory protein cascade and activated mTORC1. In contrast, the knockout of DEPDC5 partially blocked the ability of small molecule inhibitors against Pim and AKT kinases both singly and in combination to suppress tumor growth and mTORC1 activity in vitro and in vivo. In animal experiments knocking in a glutamic acid (S1530E) in DEPDC5, a phospho mimic, in tumor cells induced a significant level of resistance to Pim and the combination of Pim and AKT inhibitors. Our results indicate a phosphorylation-dependent regulatory mechanism targeting DEPDC5 through which Pim1 and AKT act as upstream effectors of mTORC1 to facilitate proliferation and survival of cancer cells.
The proviral integration site for Moloney murine leukemia virus (PIM) serine/threonine kinases have an oncogenic and prosurvival role in hematological and solid cancers. However, the mechanism by which these kinases drive tumor growth has not been completely elucidated. To determine the genes controlled by these protein kinases, we carried out a microarray analysis in T‐cell acute lymphoblastic leukemia (T‐ALL) comparing early progenitor (ETP‐ALL) cell lines whose growth is driven by PIM kinases to more mature T‐ALL cells that have low PIM levels. This analysis demonstrated that the long noncoding RNA (lncRNA) H19 was associated with increased PIM levels in ETP‐ALL. Overexpression or knockdown of PIM in these T‐ALL cell lines controlled the level of H19 and regulated the methylation of the H19 promoter, suggesting a mechanism by which PIM controls H19 transcription. In these T‐ALL cells, the expression of PIM1 induced stem cell gene expression (SOX2, OCT‐4, and NANOG) through H19. Identical results were found in prostate cancer (PCa) cell lines where PIM kinases drive cancer growth, and both H19 and stem cell gene levels. Small molecule pan‐PIM inhibitors (PIM‐i) currently in clinical trials reduced H19 expression in both of these tumor types. Importantly, the knockdown of H19 blocked the ability of PIM to induce stem cell genes in T‐ALL cells, suggesting a novel signal transduction cascade. In PCa, increases in SOX2 levels have been shown to cause both resistance to the androgen deprivation therapy (ADT) and the induction of neuroendocrine PCa, a highly metastatic form of this disease. Treatment of PCa cells with a small molecule pan‐PIM‐i reduced stem cell gene transcription and enhanced ADT, while overexpression of H19 suppressed the ability of pan‐PIM‐i to regulate hormone blockade. Together, these results demonstrate that the PIM kinases control the level of lncRNA H19, which in turn modifies stem cell gene transcription regulating tumor growth.
Anemia of chronic disease (ACD) is an inflammatory cytokine driven disease characterized by hypoferremia despite adequate iron stores. This is largely due to hepcidin, a master regulator of iron homeostasis, which blocks enterocytes from absorbing iron and preventing iron release from macrophages by binding to ferroportin. It is known that bone morphogenetic proteins (BMP) up-regulate hepcidin by activating the SMAD signaling pathway through the activin-like kinase receptor 2 (ALK2). Therefore, ALK2 has emerged as a potential therapeutic target to modulate hepcidin levels and treat ACD. We have developed a novel series of small molecule ALK2 inhibitors with promising activity in preclinical models of ACD. Using well-established cell-based and animal models of hepcidin signaling and anemia, we optimized and validated the activity of the most promising preclinical lead candidates. These compounds demonstrate significant activity in downregulating hepcidin expression in BMP-induced cell culture studies at concentrations of 100 nM or lower. Importantly, this hepcidin lowering activity was observed at concentrations that exhibited no cytotoxicity suggesting the compounds have a clean selectivity profile. The compounds also demonstrated remarkable activity in animal models of anemia, including an acute model induced by the administration of turpentine oil and a more chronic model induced by tumor formation and growth. Treatment with the lead candidates completely reversed the induction of hepcidin expression in these models and also decreased the symptoms of anemia as measured by serum iron and red blood cell levels. From these data, we have nominated a candidate to advance into IND-enabling studies that has favorable drug-like properties. We anticipate a clinical development strategy that focuses on anemia of cancer with subsequent expansion into anemia associated more broadly with other inflammatory and chronic diseases Disclosures Kim: Tolero Pharmaceuticals: Employment. Maughan:Tolero Pharmaceuticals: Employment. Soh:Tolero Pharmaceuticals: Employment. Bearss:Tolero Pharmaceuticals: Employment. Bahr:Tolero Pharmaceuticals: Employment. Bearss:Tolero Pharmaceuticals: Employment. Warner:Tolero Pharmaceuticals: Employment, Equity Ownership, Patents & Royalties.
Despite significant efforts, the clinical mechanism of action of hypomethylating agents such as 5-azacytidine (5-aza) is still poorly understood. 5-aza is currently indicated for the treatment of patients with myelodysplastic syndrome (MDS). While 5-aza has achieved good single-agent activity in acute myeloid leukemia (AML), complete response rates remain low when used as a single agent. In a recent report aimed at identifying rational therapeutic combinations with 5-aza, Bogenberger and colleagues identified multiple BCL-2 family member/BH3-containing therapeutic targets, which synergize with 5-aza when inhibited genetically or pharmacologically. The CDK9 inhibitor, alvocidib, has achieved significant improvement in complete response rates of newly diagnosed AML patients when administered before cytarabine and mitoxantrone (FLAM regimen) in a randomized multi-center Phase 2 trial when compared to 7+3 standard of care treatment. Recent reports suggest that the transcriptional repression of key anti-apoptotic proteins (eg., MCL-1) mediated by alvocidib's CDK9 inhibition, drive the pro-apoptotic activity of alvocidib in the FLAM regimen. We, therefore, hypothesized that alvocidib and 5-aza would synergize therapeutically in the treatment of AML by means of transcriptional repression of MCL-1 and sensitization to 5-aza. In this report, we demonstrate that treatment of AML cell lines with alvocidib inhibits both mRNA and protein expression of MCL-1 in a time and concentration-dependent fashion. Pre-treatment of cells with alvocidib, to repress MCL-1 expression prior to 5-aza treatment, reduced the 5-aza cell viability EC50 more than 2.5-fold, from 1.8 µM to 0.6 µM in MV4-11 cells. The alvocidib/5-aza combination also resulted in synergistic increases in caspase activity relative to either single agent within the combination, at multiple dose levels. Therefore, following reports suggesting inhibition of BCL-2 family members including MCL-1, sensitizes cells to 5-aza, our data suggest that the alvocidib/5-aza combination may constitute a viable therapeutic regimen. We also conclude that a CDK9 inhibitor/5-aza combination may be an effective clinical approach for the treatment of AML. Disclosures Kim: Tolero Pharmaceuticals: Employment. Soh:Tolero Pharmaceuticals: Employment. Bearss:Tolero Pharmaceuticals: Employment. Lee:Tolero Pharmaceuticals: Employment. Peterson:Tolero Pharmaceuticals: Employment. Whatcott:Tolero Pharmaceuticals: Employment. Siddiqui-Jain:Tolero Pharmaceuticals: Employment. Weitman:Tolero Pharmaceuticals: Employment. Bearss:Tolero Pharmaceuticals: Employment. Warner:Tolero Pharmaceuticals: Employment.
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